Tampon with enhanced leakage protection

ABSTRACT

This invention relates to an improved absorbent tampon having improved leakage performance. Tampons, having a primary absorbent member which is constructed from an absorbent material compressed to a self-sustaining form and a mass of secondary absorbent material are disclosed. The mass of secondary absorbent material may be a multiple pieces or one piece. The secondary absorbent material may be attached to the primary absorbent member, the withdrawal cord, or both, or may be integral with one or both of these members. The withdrawal cord of the tampon may have absorbent and non-absorbent zones, especially when the mass of secondary absorbent material is attached to the withdrawal cord. The mass of secondary absorbent material preferably has a lower total absorbency than the primary absorbent member. Preferably, the mass of secondary absorbent material is provided with a driving force to direct fluid toward the primary absorbent member.

CROSS REFERENCE TO RELATED APPLICATIONS

This is a division of Ser. No. 09/309,467, filed on May 10, 1999, nowU.S. Pat. No. 6,258,075, which is a continuation-in-part of Ser. No.09/287,994 filed on Apr. 8, 1999 now U.S. Pat. No. 6,206,867.

FIELD OF THE INVENTION

This invention relates to absorbent tampons. More particularly, theinvention relates to an improved absorbent tampon having increasedleakage protection. This is accomplished with a tampon comprising aprimary absorbent member and a mass of secondary absorbent materialdisposed proximate the withdrawal end of the primary absorbent member.

BACKGROUND OF THE INVENTION

A wide variety of absorbent catamenial tampons have long been known inthe art. Most currently commercially available tampons are made from atampon pledget which has been compressed into a substantiallycylindrical form. Tampon pledgets of a variety of types andconstructions have been described in the art. Prior to compression, thepledget may be rolled, spirally wound, folded, or assembled as arectangular pad of absorbent material. Tampons made from a generallyrectangular pledget of absorbent material have been popular andsuccessful in the market.

The absorbent catamenial tampons now in use typically comprise absorbentmembers which are compressed to a generally cylindrical form aboutthree-eighths to one-half inch (about 1.0 cm to 1.3 cm) in diameter andfrom about 2 cm to 7 cm in length. In order to provide the desired totalabsorbency, these absorbent members are usually formed from batts largerin size than the vaginal orifice, which are then compressed to the size(with a corresponding increase in rigidity) indicated above in order tofacilitate insertion. As fluid is absorbed, these compressed tampons areexpected to re-expand toward their original pre-compressed size, and toeventually become large enough to effectively cover the vaginal cavityagainst fluid leakage or bypass. While it has been found that thesecompressed tampons perform their intended function tolerably well, eventhe best of them do not always re-expand sufficiently, or fast enough,to provide good coverage against leakage.

The prior art has long recognized various mechanisms by which tamponsmight fail to deliver superior performance. One such mechanism is oftenreferred to in the art as “bypass” failure. Bypass failure occurs whenthe menses travels along the length of the vagina without contacting thetampon, i.e. the tampon fails to intercept the flowing menses.

A variety of approaches have been attempted in the prior art to addressbypass and other forms of tampon failure. One series of attempts hasincluded the use of a conventional cylindrical, compressed tampon incombination with a secondary or “backup” structure. One example of suchan attempt is described in U.S. Pat. No. 3,101,714 issued to Penska. ThePenska device consists of a typical elongated cylindrical body ofabsorbent material with an absorbent withdrawal cord. A plug or pad ofabsorbent material is slidably mounted on the cord. During normal flowtimes, the plug member may be removed from the cord. In times of heavierflow, the plug may be slid upward on the cord, after insertion, to beheld in place by the sphincter muscles of the vagina. While appearing toaddress some of the problems associated with bypass flow, the Penska,device suffers from some significant drawbacks. For example, thewithdrawal cord of the device is absorbent which has the tendency toretain deposited fluid along the entire length of the cord and,consequently, outward of the orifice of the vagina. Additionally, theslidable plug of the absorbent device resides at least partiallyexternally to the vagina and is held in place by the sphincter musclesthereof. Because the plug of the Penska device cannot be slid into placeuntil after insertion of the tampon portion, a completely internaldisposition (i.e. intervaginal placement) of the plug cannot beachieved.

Another prior art approach is described in U.S. Pat. No. 2,123,750issued to Schulz. The Schulz device consists of an essentiallyconventional cylindrically shaped absorbent portion with a withdrawalend “flare” of material attached thereto. The withdrawal end flare,however, is comprised of a non-absorbent material and extends outwardlyin the radial direction beyond the outer diameter of the cylindricalabsorbent portion. This reduces both the comfort associated with theSchulz device, as well as its effectiveness, since the additionalmaterial is non-absorbent and, therefore, of marginal usefulness.

Yet another approach is described in U.S. Pat. No. 3,307,506 also issuedto Penska. This device generally consists of a tampon attached by thewithdrawal cord thereof to a sanitary napkin. This device also suffersfrom the disadvantage that only external placement of the secondaryabsorbent member is possible.

While many of the above-described devices and other tampons currentlyavailable have been successful and have gained acceptance in themarketplace, the search for an improved absorbent tampon has continued.Each of the above-described devices suffers from certain drawbacks, asnoted, which are addressed by the development of the present invention.

During development of the present invention, it has been found that itis desirable to provide a catamenial tampon which may be constructed ofmaterials such as rayon and cotton which have long been used in the artfor absorption of menstrual and other vaginal discharges. Such materialsare accepted as safe and effective for such in-vivo application, arereadily available, and are sufficiently inexpensive for disposableproduct application. It is also desirable to design a tampon which maybe inserted digitally or through the use of conventional “tube andplunger” applicators since such applicators are well accepted byconsumers and are easy and inexpensive to manufacture. It is alsodesired to provide a tampon which is comfortable and which does notdepart from currently approved regulatory absorbency ranges. A superiordesign will achieve all of these goals, while also minimizing bypassleakage associated with the tampon. This is accomplished through theunique design of the present invention which resides in an optimallocation within the vaginal vault and which is provided with a superiormechanism for bypass prevention.

SUMMARY OF THE INVENTION

This invention relates to catamenial tampons, and more particularly, toimproved tampons having a primary absorbent member which is constructedfrom an absorbent material compressed to a self-sustaining form. Theprimary absorbent member of the tampon has an insertion end and awithdrawal end.

In one embodiment, the tampon preferably includes a withdrawal mechanismattached to the primary absorbent member which extends beyond at leastthe withdrawal end for removal of the tampon. The tampon also preferablyincludes in such an embodiment a mass of secondary absorbent materialfixedly attached to the withdrawal cord proximate the withdrawal end ofthe primary absorbent member. The absorbency of the primary absorbentmember in this execution is preferably greater than the absorbency ofthe secondary absorbent member. Additionally, the mass of secondaryabsorbent material is preferably more hydrophilic than the withdrawalmechanism at least along the location of attachment of the mass ofsecondary absorbent material to the withdrawal mechanism.

In another embodiment, the tampon preferably includes an embodiment amass of secondary absorbent material proximate the withdrawal end of theprimary absorbent material. The density of the secondary absorbentmaterial is preferably lower than the density of the primary absorbentmember. The primary absorbent member and the secondary material arepreferably configured such that the primary absorbent member and thesecondary absorbent material reside entirely within the vaginal space ofthe user during wear without extending outwardly therefrom. In thissecond embodiment, the secondary absorbent material may be joined to awithdrawal mechanism or to the primary absorbent member.

In an additional embodiment, the tampon preferably includes a mass ofsecondary absorbent material proximate the withdrawal end the primaryabsorbent member, wherein the diameter of the primary absorbent memberis larger than the diameter of the mass of secondary absorbent material.In this third embodiment, the secondary absorbent material is preferablyjoined to a withdrawal mechanism or to the primary absorbent member.Preferably, the primary absorbent member and the secondary absorbentmaterial are configured such that the primary absorbent member and thesecondary material reside entirely within the vaginal space of thewearer without extending outwardly therefrom.

In any of the above-described embodiments, the secondary absorbentmaterial may preferably be substantially non-compressed. The secondaryabsorbent material may be substantially axially centered about thewithdrawal mechanism. The tampon may be provided with a gap between thewithdrawal end of the primary absorbent member and the start of thesecondary absorbent material. Preferably, the diameter of the primaryabsorbent core of the tampon is greater than the diameter of thesecondary absorbent material. The secondary absorbent material may beprovided in a plurality of discrete pieces of absorbent material. Theprimary absorbent member may optionally comprise a layer structure priorto being compressed to a self-sustaining form. The primary absorbentmember may also optionally comprise a chevron shaped pad prior to beingcompressed to a substantially cylindrical self sustaining form.

One preferred method of making the tampon may include the steps of:providing a continuous strip of absorbent material and cutting thisstrip into a plurality of individual absorbent pads. The first end ofeach of these pads has a notch and the second end of each of these padshas a tab of absorbent material, the tab being integral with the pad. Astep of attaching a withdrawal cord to at least a portion of each of thepads is also included. The method also includes a step of compressingeach pad in at least a radial direction to form a tampon having aprimary absorbent member and a mass of secondary absorbent material. Thetab portion of the pad results in the mass of secondary absorbentmaterial and the mass of secondary absorbent material remains lesscompressed than the primary absorbent member.

BRIEF DESCRIPTION OF THE DRAWINGS

While the specification concludes with claims particularly pointing outand distinctly claiming the subject matter which is regarded as formingthe present invention, it is believed that the invention will be betterunderstood from the following description taken in conjunction with theaccompanying drawings, in which:

FIG. 1 is a front view of a tampon of the present inventionincorporating a primary absorbent member and a mass of secondaryabsorbent material.

FIG. 2 is a perspective view a typical tampon pledget prior tocompression into the primary absorbent member of a tampon of the presentinvention.

FIG. 3 is a perspective view of another tampon pledget prior tocompression into the primary absorbent member of a tampon of the presentinvention in which the pledget is chevron shaped structure.

FIG. 4 is front view of an additional embodiment of a tampon of thepresent invention in which there is a gap between the withdrawal end ofprimary absorbent member and the mass of secondary absorbent material.

FIG. 5 is a front view of an embodiment of a tampon of the presentinvention in which the mass of secondary absorbent material is providedin the form of a plurality of discrete pieces of absorbent material.

FIG. 6 is a front view of an embodiment of a tampon of the presentinvention in which the mass of secondary absorbent material is attachedto the primary absorbent member.

FIG. 7 is a front view of an embodiment of a tampon of the presentinvention in which a portion of the mass of secondary absorbent materialis attached to the primary absorbent member and a portion of the mass ofsecondary absorbent material is attached to the withdrawal cord.

FIG. 8 shows one method of making one or more tampons of the presentinvention in which multiple pads may be cut from a continuous strip ofabsorbent material.

FIG. 9 shows a pad which has been cut from the continuous strip ofabsorbent material of FIG. 8 and to which a withdrawal cord has beenattached prior to compression.

DETAILED DESCRIPTION OF THE INVENTION

This present invention is directed to an improved absorbent tamponhaving increased leakage protection. It has been found duringdevelopment of the present invention that there are several potentialmechanisms beyond simple bypass flow which may contribute to tamponleakage. Without wishing to be bound by theory, some of these mechanismsmay be explained by the following observations. It has been found thatmany current tampons show stains on the withdrawal cord associated withincidents of tampon leakage. Therefore, the withdrawal cord of manycurrent tampons may be offering an “escape” route for menses present atthe base of the vagina.

During a tampon change, some residual menses may be left near theintroitus of the vagina. This may be fluid which was previouslyabsorbed, but which subsequently “squeezed out” of the tampon as it waswithdrawn through the sphincter of the vagina. Such residual fluid,particularly if located near the introitus (i.e. in the lower vaginalvault) may not be effectively absorbed by the replacement tampon. Thisis particularly true of many current tampons which are typicallyinserted somewhat more deeply within the vaginal canal. Thesemechanisms, as well as bypass described above, and other leakagemechanisms are addressed by the development of the present invention.

FIG. 1 shows one embodiment of such an absorbent tampon, tampon 20. Thepresent invention, however, is not limited to a structure having theparticular configuration shown in the drawings.

As used herein the term “tampon” refers to any type of absorbentstructure which is inserted into the vaginal canal or other bodycavities for the absorption of fluid therefrom. Typically, tampons areconstructed from an absorbent material which has been compressed ineither the radial direction, the axial direction, or both in order toprovide a tampon which is of a size and stability to allow insertionwithin the vagina or other body cavity. A tampon which has been socompressed is referred to herein as a “self-sustaining” form. That is,the degree of compression applied to the absorbent material of thetampon pledget is sufficient so that in the subsequent absence of theexternal forces, the resulting tampon will tend to retain its generalshape and size.

It will be understood by one of skill in the art that thisself-sustaining form need not, and preferably does not persist duringactual use of the tampon. That is once the tampon is inserted and beginsto acquire fluid, the tampon will begin to expand and may lose itsself-sustaining form.

As used herein the terms “pledget” or “tampon pledget” are intended tobe interchangeable and refer to a construction of absorbent materialprior to the compression of such construction into a tampon as describedabove. Tampon pledgets are sometimes referred to as a tampon blank, or asoftwind, and the term “pledget” is intended to include such terms aswell.

As used herein the terms “vaginal cavity,” “within the vagina” and“vaginal interior,” are intended to be synonymous and refer to theinternal genitalia of the human female in the pudendal region of thebody. The term “vaginal cavity” as used herein is intended to refer tothe space located between the introitus of the vagina (sometimesreferred to as the sphincter of the vagina) and the cervix and is notintended to include the interlabial space, including the floor ofvestibule. The externally visible genitalia generally is not includedwithin the term “vaginal cavity” as used herein.

The primary absorbent member 21 (sometimes also referred to as the“absorbent core”) of the tampon 20 shown in FIG. 1 has an insertion end30 and a withdrawal end 34. The primary absorbent member 21 may becompressed into a generally cylindrical configuration in the radialdirection, the axial direction, or in both the radial and axialdirections. While the primary absorbent member 21 is preferablycompressed into a substantially cylindrical configuration, other shapesare also possible. These may include shapes having a cross section whichmay be described as rectangular, triangular, trapezoidal, semi-circular,or other suitable shapes.

The primary absorbent member 21 of the tampon 20 of the presentinvention may be formed from any suitable tampon pledget, such as tamponpledget 28 shown in FIG. 2. Typically, the secondary absorbent material60, described in greater detail below, is joined to either a withdrawalmechanism, such as withdrawal cord 48, the primary absorbent member 21itself, or both. This joining of the secondary absorbent material mayoccur subsequently to compression of the pledget 28 to form the primaryabsorbent member 21. In some variations it may be desirable to attachsome or all of the secondary absorbent material 60 to the pledget 28,the withdrawal mechanism, such as withdrawal cord 48, or both, prior tocompression of the pledget 28 to a self-sustaining form (i.e. theabsorbent member 21). In one preferred method of making a tampon 20 ofthe present invention, described more fully below, the mass of secondaryabsorbent material 60 is integral with the primary absorbent member 21prior to compression of the pledget. In any of the above mentionedmanners of construction, the secondary absorbent material 60 ispreferably not compressed; or, if compressed, is not compressed to thesame degree as the primary absorbent member 21.

The tampon pledget 28 portion of the tampon 20 which will be compressedto form the primary absorbent member 21 may be any suitable shape, size,material, or construction. In the embodiment shown in FIG. 2, pledget 28is a batt of absorbent material which is a generally rectangular pad ofabsorbent material.

While the pledget 28 shown in FIG. 2 is generally rectangular, othershapes such as trapezoidal, triangular, hemispherical, and chevronshaped are also acceptable. The pledget 28 may be a laminar structurecomprised of integral or discrete layers. In the embodiment shown inFIG. 2, the pledget 28 may comprise outer layers 79 and at least oneintermediate layer 81 positioned between the outer layers 79. In otherembodiments, the pad need not have a layered structure at all. Thepledget 28 may comprise a folded structure, may be rolled, may comprisea “petal” structure or any other of the structures which are known inthe art with respect to tampon pledgets.

The pledget 28, and consequently, the resulting primary absorbent member21 of the tampon 20 may be constructed from a wide variety ofliquid-absorbing materials commonly used in absorbent articles such asrayon, cotton, or comminuted wood pulp which is generally referred to asairfelt. Examples of other suitable absorbent materials include crepedcellulose wadding; meltblown polymers including coform; chemicallystiffened, modified or cross-linked cellulosic fibers; synthetic fiberssuch as crimped polyester fibers; peat moss; foam; tissue includingtissue wraps and tissue laminates; or any equivalent material orcombinations of materials, or mixtures of these. Preferred absorbentmaterials comprise cotton, rayon (including tri-lobal and conventionalrayon fibers, and needle punched rayon), folded tissues, wovenmaterials, nonwoven webs, synthetic and/or natural fibers. The tampon 20and any component thereof may comprise a single material or acombination of materials. Additionally, superabsorbent materials, suchas superabsorbent polymers or absorbent gelling materials may beincorporated into the tampon 20.

In the preferred embodiment shown in FIGS. 1 and 2, the pledget 28 andresulting primary absorbent member 21 is formed of a soft absorbentmaterial such as rayon, cotton (including either long fiber cotton orcotton linters) or other suitable natural or synthetic fibers orsheeting. The materials for the tampon 20 can be formed into a fabric,web, or batt that is suitable for use in the pledget 28 by any suitableprocess such as airlaying, carding, wetlaying, hydroentangling, or otherknown techniques.

In one non-limiting preferred embodiment, the tampon pledget 28 andresulting primary absorbent member 21 comprise rayon, cotton, orcombinations of both materials. The rayon used in the tampon pledget 28may be any suitable type typically used in disposable absorbent articlesintended for in vivo use. Such acceptable types of rayon include GALAXYRayon (a tri-lobed rayon structure) available as 6140 Rayon fromCourtaulds Fibers Ltd., of Hollywall, England. SARILLE L rayon (a roundfiber rayon), also available from Courtaulds Fibers Ltd. is alsosuitable. Any suitable cotton material may be used in the tampon pledget28. Suitable cotton material includes, long fiber cotton, short fibercotton, cotton linters, T-fiber cotton, card strips, and comber cotton.Preferably, the cotton layers should be a scoured & bleached cottonabsorbent with a glycerin finish, a leomin finish, or other suitablefinish.

The absorbent material of the pledget 28 may be surrounded with a liquidpermeable overwrap material, if desired. Such overwrap materials maycomprise rayon, cotton, bicomponent fibers, or other suitable natural orsynthetic fibers known in the art. If the pledget 28 of the presentinvention is layered, the layers may comprise different materials. Forexample, in the embodiment shown in FIG. 2 the outer layers 79, maycomprise primarily rayon, while the intermediate layer 81 or layers maycomprise primarily cotton. Optionally, the entire pledget 28 maycomprise a uniform or nonuniform blend of materials throughout.

The pledget 28 may be any suitable size and thickness suitable forcompression into a tampon having a size which facilitates insertion. Asize similar to those of conventional currently available tampons hasbeen found to work well. A typical size for such pledgets may be about 9cm in length and about 4.5 cm in width. One preferred range for theoverall basis weight is from about 150 g/m² to about 750 g/m².Optionally, pledgets 28 which are shorter and wider than the rangesgiven above may also be desirable in order to facilitate width-wiseexpansion of the tampon in use.

A withdrawal mechanism, such as withdrawal cord 48, examples of whichare shown in FIGS. 1-2, is preferably joined to the tampon 20 forremoval of the tampon after use. The withdrawal mechanism is, preferablyjoined to at least the primary absorbent member 21 and extends beyond atleast the withdrawal end 34 thereof. Any of the withdrawal cordscurrently known in the art may be used as a suitable withdrawalmechanism. In addition, the withdrawal mechanism can take on other formssuch as a ribbon, loop, tab, or the like. The withdrawal mechanism maybe integral with, or an extension of another element of the tampon, suchas an overwrap as described above. Additionally, as discussed in greaterdetail below, the withdrawal mechanism may be integral with the mass ofsecondary absorbent material.

The withdrawal cord 48 or other withdrawal mechanism may be attached inany suitable manner known in the art including sewing, adhesiveattachment, or a combination of known bonding methods. The tampon 20 ofthe present invention may also be provided with more than one withdrawalmechanism such as multiple withdrawal cords 48. For example, twowithdrawal cords 48 or other withdrawal mechanisms such withdrawalribbons may be attached down the length of the pledget 28 and extendfrom the withdrawal end thereof. In such an instance, the mass ofsecondary absorbent material, may be joined to one or both of thewithdrawal cords 48 or other withdrawal mechanisms.

Especially when the mass of secondary absorbent material 60 is joined tothe withdrawal cord 48 or other withdrawal mechanism, the withdrawalcord 48 is preferably non-absorbent along at least the location of suchattachment. As used herein, the term “non-absorbent” refers to astructure that does not retain a significant portion of deposited fluidin its structure. The entire withdrawal cord 48 or other withdrawalmechanism may be made non-absorbent, if desired. The materialscomprising the withdrawal cord may be inherently non-wettable orhydrophobic, or they may be treated to provide such properties. Forexample, a coating of wax may be applied to the withdrawal cord 48 todecrease or eliminate its absorbency. Other means for providing amaterial suitable for use as a withdrawal cord 48 which is non-absorbentand/or non-wicking are known in the art. For example, U.S. Pat. No.5,458,589 issued to Comin-DuMong describes one such approach. Thewithdrawal cord 48 or other withdrawal mechanism need not necessarily benon-wicking, even if a non-absorbent withdrawal cord is desired. Forexample, it may be desirable to provide a withdrawal cord 48 in which atleast a portion of the cord has a tendency to wick deposited fluidupwardly toward the withdrawal end 34 of the primary absorbent memberand into the structure thereof.

The withdrawal cord 48, withdrawal ribbon, or other withdrawal mechanismneed not have uniform properties throughout its length. For example, theportion of the withdrawal cord nearest the primary absorbent member 21may be absorbent while the lower portion (i.e. furthest from the primaryabsorbent member 21) of the cord 48 or other withdrawal mechanism may benon-absorbent. Other properties such as wicking ability, hydrophilicity,density, capillary size, width, thickness, and the like may also varyalong the length of the withdrawal cord 48 or other withdrawalmechanism. In preferred embodiments, the withdrawal mechanism ispreferably flexible.

The withdrawal cord 48 or other withdrawal mechanism may be joined toany suitable location on the tampon 20. In the embodiment shown in FIGS.1-2, the withdrawal cord 48 is joined to the primary absorbent member 21(and pledget 28) and extends freely beyond the withdrawal end 34 of theprimary absorbent member 21. The withdrawal cord 48, is typicallyattached to the tampon pledget 28 while the pledget 28 is stilluncompressed as shown in FIG. 2. The withdrawal cord 40 may be attachedalong the entire length one major surface of the pledget 28 (such as bystitching) and hang free from one end, such as the withdrawal end 34.

The tampon 20 of the present invention is also provided with a mass ofsecondary absorbent material 60. The secondary absorbent material 60 maycomprise one piece of material as shown, for example, in FIG. 1, or maycomprise multiple discrete pieces as shown, for example in FIG. 5. Thesecondary absorbent material 60 may be arranged in a wide variety ofshapes and configurations and may be generally cylindrical, spherical,semi-spherical, disc-like, planar, rectangular, “skirt-like” in shape,or may comprise “tufts” or whips of absorbent elements.

The size of the secondary absorbent material 60 may vary according toits shape. For example, in the embodiment shown in FIG. 1 the mass ofsecondary absorbent material 60 is generally cylindrical and elongated.The length of the mass of secondary absorbent material is measured inthe direction generally parallel to a line running through the axis ofthe tampon extending through the insertion end and withdrawal end of theprimary absorbent member 21. In the embodiment shown in FIG. 1, thelength of the mass of secondary absorbent material 60 may be betweenabout 10 mm and about 55 mm, more preferably 25 mm and about 35 mm.

Caliper measurements given herein are measured using an AMES gage with a0.25 psig load and a 0.96 inch diameter foot. Those skilled in the artwill recognize that if a 0.96 inch diameter foot is not appropriate fora particular sample size, the foot size may be varied while the load onthe gauge is accordingly varied to maintain a confining pressure of 0.25psig. The caliper measurement refers to the diameter of the mass ofsecondary absorbent material 60 or to its widest dimension in thenon-length direction. If the mass of secondary absorbent material 60 isnot exactly or substantially cylindrical, “diameter” may be interpretedto mean the widest caliper measurement as defined herein in thenon-length direction. The diameter, or caliper, of the mass of secondaryabsorbent material 60 shown in FIG. 1 is preferably from about 2 mm toabout 30 mm, more preferably from about 7 to about 15 mm.

Any suitable amount of fiber may be used for the mass of secondaryabsorbent material 60. In the preferred embodiment shown in FIG. 1,about 0.05 g of absorbent fiber is used. Preferably, the mass ofsecondary absorbent material 60 is constructed such that it will remainflexible, in order to facilitate comfort in use.

The mass of secondary absorbent material 60 is joined to the tampon 20at any suitable location generally proximate the withdrawal end 34 ofthe primary absorbent member 21. In the embodiment shown in FIG. 1, themass of secondary absorbent material 60 is joined to the withdrawal cord48 and is generally centered axially around the cord 48. It is alsopossible to attach such a mass of secondary absorbent material 60 to thewithdrawal end 34 of the primary absorbent member 21 either in additionto, or in lieu of, attachment to the withdrawal cord 48.

In the embodiment shown in FIG. 4, the mass of secondary absorbentmaterial 60 is joined to the withdrawal cord 48. The mass of secondaryabsorbent material 60 in FIG. 4, however, is positioned at a locationslightly lower along the withdrawal cord 48 than is the case with FIG.1, thereby creating a “gap” 55 between the withdrawal end 34 of theprimary absorbent member and the uppermost part of the mass of secondaryabsorbent material 60. The length of the gap 55 along the withdrawalcord 48 may preferably be in the range of from about 1 mm to about 15mm. As shown in FIG. 5, the mass of secondary absorbent material 60 maycomprise a series of discrete pieces of absorbent material 62. In theembodiment shown in FIG. 5, these discrete pieces of absorbent material62 are attached along the withdrawal cord 48 of the tampon 20.

In the embodiment shown in FIG. 6, the mass of secondary absorbentmaterial 60 is joined to the withdrawal end 34 of the primary absorbentmember. The mass of secondary absorbent material 60 shown in FIG. 6 isin the form of a series of absorbent strands or “tufts” 64 of materialdepending from the withdrawal end 34 of the primary absorbent member 21.These absorbent strands or tufts 64 can also be substantially continuousor be constructed from one piece of material arranged in the form of a“skirt” around the withdrawal end 34 of the primary absorbent member 34.

As shown in FIG. 7, it is possible to combine different variations onthe form of the secondary absorbent material 60 described above in thesame tampon 20. For example, FIG. 7 shows the combination of a singlepiece of secondary absorbent material 60 joined to the withdrawal cord48 used in combination with additional secondary absorbent material 60in the form of absorbent strands or tufts 64.

In any of the embodiments described above, or in variations thereof, thelocation of the secondary absorbent material should preferably begenerally proximate the withdrawal end of the main absorbent portion 21of the tampon 20. In preferred embodiments, the length of the primaryabsorbent member 21 is in the range from about 2 cm to about 7 cm. Thewithdrawal cord 48 of the tampon 20 preferably extends below thewithdrawal end 34 of the primary absorbent portion about 10 cm.

Both the primary absorbent member 21 and the mass of secondary absorbentmaterial 60 preferably reside entirely within the vaginal cavity of thewearer during use of the tampon 20. This is achieved by the relativelycloseness of the mass of secondary absorbent material 60 to thewithdrawal end 34 of the primary absorbent member 21 as well of therelative size of such mass 60 compared to the overall size of thetampon. In particularly preferred embodiments, only the withdrawal cord48 or other withdrawal mechanism (without any associated secondaryabsorbent material 60) resides externally to the orifice of the vagina.

The mass of secondary absorbent material 60 proximate to the withdrawalend of the primary absorbent member 21 adds an effective area of thetampon 20 which is placed “lower” within the vaginal vault (as comparedto the effective area of current tampons). Because the secondaryabsorbent material 60 is preferably located proximate the withdrawal end34 as described, optimal placement of the effective area of the tampon20 is achieved by the present invention. The tampon 20 may be insertedin the same manner as most currently available conventional tampons, andthe secondary absorbent material (which is preferably fixed and notslidable) will provide absorbent capacity within the lower vaginalvault. Additionally, the preferred configurations and properties of themass of secondary absorbent material 60 described herein allows for an“operable” portion of the tampon 20 be provided in the lower vaginalvault without introduction of wearer comfort concerns. The lower regionof the vaginal vault is highly sensitive and prior art devices locatedin this region had a tendency to cause discomfort or unacceptablewearing awareness as opposed to devices more fully inserted within thevaginal canal. This concern is not presented by the tampon 20 of thepresent invention because the portion of the tampon designed to residein the lowest portion of the vaginal cavity (i.e. the mass of secondaryabsorbent material 60) is preferably softer, smaller, and less densethan the primary absorbent member.

The term “joined” or “attached” as used herein, encompassesconfigurations in which an element is directly secured to anotherelement by affixing the element directly to the other element;configurations in which the element is indirectly secured to the otherelement by affixing the element to intermediate member(s) which in turnare affixed to the other element; and configurations in which oneelement is integral with another element; i.e., one element isessentially part of the other element.

The mass of secondary absorbent material 60 may be joined to thewithdrawal cord 48 (or other withdrawal mechanism) or the withdrawal end34 of the primary absorbent member 21, or both, by any variety of means.For example, the mass of secondary absorbent material 60 may be joinedto one or both of the withdrawal cord 48 or the withdrawal end 34 of theprimary absorbent member 21 using any suitable adhesive. Such adhesivemay extend continuously along the length of attachment or it may beapplied in a “dotted” fashion at discrete intervals. Alternatively, themass of absorbent material 60 may be joined to the withdrawal cord 48 orprimary absorbent member 21 by stitching. Such stitching may use cottonor rayon thread. Other attachment mechanisms include thermally bonding(for example where the mass of secondary absorbent material 60 hasthermally bonded fibers or other thermally bonding materialsincorporated therein), fusion bonding, or any other suitable means knownin the art for joining such materials.

The mass of secondary absorbent material 60 may be constructed from anyof the materials described above for suitable as use in the primaryabsorbent member 21. Preferably, the same materials are used in theconstruction of the mass of secondary absorbent material 60 as are usedin the primary absorbent member 21. Rayon and cotton are especiallypreferred materials for inclusion in the mass of secondary absorbentmaterial 60. The mass of secondary absorbent material 60 may alsoinclude a suitable nonwoven structure as described above. A layer orsheet of secondary absorbent material 60 may be formed independently ofthe primary absorbent member 21 and slipped around the withdrawal cord48 and attached thereto. The withdrawal cord 48 could be wound with anabsorbent material, fiber, yarn, or other structure, in at least theportion of the cord 48 located proximate to the withdrawal end 34 of theprimary absorbent member 21.

The mass of secondary absorbent material 60 may also be integral withany other component of the tampon 20. For example, the mass of secondaryabsorbent material 60 may comprise an extension of the primary absorbentmember (although preferably a less compressed portion). The mass ofsecondary absorbent material 60 may be in the form of a sheet or layerof absorbent material. For example, one or more internal layers 81 suchas that shown in FIG. 2 could extend beyond the withdrawal end 34 of thepledget 28 either along its entire width or a portion of its width toform the mass of secondary absorbent material. A portion of theoverwrap, if included, could be extended as described herein to form themass of secondary absorbent material. Additionally, the withdrawalmechanism itself could serve as both such a withdrawal mechanism and thesecondary absorbent material. An example of such an embodiment is aribbon of material which serves as the withdrawal mechanism. The upperportion of this ribbon could be absorbent and serve as the mass ofsecondary absorbent material while the lower portion of such ribbon isnon-absorbent.

The mass of secondary absorbent material 60 is preferably absorbent.While the specific absorbency of the secondary absorbency material 60may be less than, equal to, or greater than that of the primaryabsorbent member 21; preferably, the total absorbency of the mass ofsecondary absorbent material 60 is less than that of the primaryabsorbent member 21. In embodiments such as that shown in FIG. 5 wherethe mass of secondary absorbent material 60 is comprised of multiplepieces of absorbent material, the primary absorbent member 21 preferablyhas a total absorbency which exceeds the total combined absorbency ofsuch multiple pieces of secondary absorbent material 60.

The mass of secondary absorbent material 60 is preferably hydrophilic.In preferred embodiments, the mass of secondary absorbent material 60may have an advancing contact angle greater than the advancing contactangle of the primary absorbent member 21 and/or the withdrawal cord 48(or other withdrawal mechanism), such that fluid is preferentiallydirected toward and absorbed by the primary absorbent member 21.Optionally, the mass of secondary absorbent material 60 may be treatedto make it less absorbent than the primary absorbent member 21.Preferably, the majority of the fluid absorbed and retained by thetampon 20 will ultimately be retained in the primary absorbent member21. In preferred embodiments, the mass of secondary absorbent material60 is more hydrophilic than the withdrawal cord 48 or other withdrawalmechanism. The withdrawal cord 48, may be made substantially hydrophobicin preferred executions. If the entire withdrawal cord 48 or otherwithdrawal mechanism is not less hydrophilic than the mass of secondaryabsorbent material 60, preferably, at least potions of the withdrawalmechanism (such as along the location of attachment of the mass ofsecondary absorbent material to the withdrawal cord) are lesshydrophilic than the mass of secondary absorbent material.

For a more detailed description of hydrophilicity and contact angles seethe following publications which are incorporated by reference herein:The American Chemical Society Publication entitled “Contact Angle,Wettability, and Adhesion,” edited by Robert F. Gould, and copyrightedin 1964; and TRI/Princeton Publications, Publication Number 459,entitled “A Microtechnique for Determining Surface Tension,” publishedin April 1992, and Publication Number 468 entitled, “Determining ContactAngles Within Porous Networks,” published in January, 1993, both editedby Dr. H. G. Heilweil.

The mass of secondary absorbent material 60 may optionally be providedwith a mechanism to preferentially direct acquired fluid toward the bodyof the primary absorbent member 21. Examples of such a driving force arethe use of a hydrophilicity gradient as described above. Othermechanisms include a density or capilarity gradient, or an osmoticdriving force. The mass of secondary absorbent material 60 may beprovided with loose fiber ends to add a textured surface to the material60. Capillary channel fibers may optionally be incorporated into themass of secondary absorbent material 60 in order to provide the drivingforce for acquired fluid described herein.

Preferably, the density of material which comprises the mass ofsecondary absorbent material 60 is lower than the density of the primaryabsorbent member 21. The mass of secondary absorbent material 60 ispreferably not compressed during formation of the tampon 20. If the massof secondary absorbent material 60 is compressed it is preferablycompressed to a lesser degree than the primary absorbent portion suchthat the resulting density of the secondary absorbent material 60 in thefinished tampon 20 remains below that associated with the primaryabsorbent member 21.

The tampon 20 of the present invention is believed to offer severaladvantages over prior art tampons. As noted previously, theincorporation of the mass of secondary absorbent material 60 providesabsorbency capacity in the lower vaginal vault. This results in a lowerdisposition of the overall “effective” surfaces of the tampon 20 withinthe vaginal vault of the wearer. Additionally, because the mass ofsecondary absorbent material is less compressed than the primaryabsorbent member 21, such material is available to immediately acquirefluid without the need for re-expansion. Previously known device, suchas that described in U.S. Pat. No. 3,101,714 (Penska) required a twostep insertion process. That is, the Penska device must be inserted,then the slidable plug must be moved into place. This plug would not befully inserted past the vaginal sphincter muscles and would have highwearing awareness due to contact with and subsequent stretching of theintroitus. The present invention, by contrast, is inserted in oneoperation, and by its design is properly positioned for optimaleffectiveness following this one-step insertion process. The tampon ofthe present invention also has the advantage that its provides theadditional benefits over current tampons described herein, but does notrequire a change in consumer use habits to use properly and effectively.The tampon of the present invention additionally may be constructed withcurrently known safe and effective materials and provides an increase inleakage protection without requiring an increase in the overallabsorbency of the tampon (as measured, e.g. by the syngyna method).

To form a tampon ready for use, the tampon pledget 28 is typicallycompressed and heat conditioned in any suitable conventional manner.Pressures and temperatures suitable for this purpose are well known inthe art. Typically, the pledget 28 is compressed in both the radial andaxial direction using any means well known in the art. While a varietyof techniques are known and acceptable for these purposes, a modifiedtampon compressor machine available from Hauni Machines, Richmond, Va.,is suitable. If the mass of secondary absorbent material 60 is attachedto the tampon 20 after compression of the pledget 28, then nomodification of the method of making a conventional compressed absorbenttampon is necessary (except of course that the mass of secondarymaterial is attached after the otherwise completed tampon is formed).

While several methods of making a tampon 20 of the present inventionwould be apparent to one of skill in the art in light of the disclosureherein, following is a description of one method of making a tampon ofthe present invention is a continuous operation in which the mass ofsecondary absorbent material is integral with the tampon pledget 28.

In such a method of making, a generally rectangular (or other suitablyshaped) pad of absorbent material is formed. FIG. 8 shows a strip ofabsorbent material formed by a suitable carding process. The cardingprocess results in a continuous strip of absorbent material 84 which maythen be cut into individual absorbent pads, such as those shown in FIG.9. The term “continuous strip” is intended to mean an elongated mass ofabsorbent material of sufficient length in the machine direction to becut into two or more individual pledgets 28. The cutting operation maybe performed (i.e. through the use of a suitably shaped cutting die)such that a “notch” 80 is formed in the insertion end of each pledget28. This notch 80 will result in an integral piece of absorbent materialwhich depends from the withdrawal end 34 of the pledget 28. The notch 80may be generally square or rectangular as shown in FIG. 9 or may betriangular, semi-circular, trapezoidal, or any of the other shapesdisclosed herein for the mass of secondary absorbent material 60. Thisnotch 80, as shown in FIG. 9 will serve as the mass of secondaryabsorbent material 60 of the finished tampon. The individual pads arethen preferably provided with a suitable withdrawal cord 48 which mayextend down the entire length of the pledget 28 and mass of secondaryabsorbent material 60.

During formation of the tampon 20 the pledget 28 (exclusive of theintegral mass of secondary absorbent material) is compressed asdescribed above. Because the mass of secondary absorbent material issmaller in the width dimension than the pledget 28, the radialcompression of the pledget 28 will not substantially compress thesecondary absorbent material 60. During the axial compression stage, ifany, only the pledget 28 portion is compressed through the use of asuitable push-rod and the mass of secondary absorbent material remainsessentially non-compressed.

The tampon 20 of the present invention may be inserted digitally orthrough the use of an applicator. If the tampon 20 is to be used fordigital insertion, it may be desirable to form the pledget from a layerof absorbent material which has been rolled into a cylindrical shape.

Any of the currently available tampon applicators may also be used forinsertion of the tampon of the present invention. Such applicators oftypically a “tube and plunger” type arrangement and may be plastic,paper, or other suitable material. Additionally, a “compact” typeapplicator is also suitable. The applicator plunger will push thecompressed primary absorbent member 21 out of the applicator whilefitting around the mass of secondary absorbent material 60.

The disclosures of all patents, patent applications (and any patentswhich issue thereon, as well as any corresponding published foreignpatent applications), and publications mentioned throughout this patentapplication are hereby incorporated by reference herein. It is expresslynot admitted, however, that any of the documents incorporated byreference herein teach or disclose the present invention. It is alsoexpressly not admitted that any of the commercially available materialsor products described herein teach or disclose the present invention.

The disclosures of all patents and patent applications referred to inthis specification (including those listed in the Cross Reference toRelated Applications Section) are hereby incorporated by reference as iffully set forth herein. While particular embodiments of the presentinvention have been illustrated and described, it would be obvious tothose skilled in the art that various other changes and modificationscan be made without departing from the spirit and scope of theinvention.

What is claimed is:
 1. An absorbent tampon having an insertion end and awithdrawal end said tampon comprising: a primary absorbent region,disposed toward said insertion end; a secondary absorbent region; awithdrawal mechanism; wherein said primary absorbent region has a firstabsorbency and a first density, said secondary absorbent region has asecond absorbency and a second density, and said withdrawal mechanismhas a third absorbency, said first absorbency being greater than saidsecond absorbency, and said second absorbency being greater than saidthird absorbency; and said second density being less than said firstdensity; and wherein said primary absorbent region is joined to saidsecondary absorbent region through a member selected from the groupconsisting of adhering with adhesives, stitching, thermal bonding, andfusion bonding.
 2. An absorbent tampon according to claim 1 wherein saidsecondary absorbent region comprises an extended portion of an overwrap.3. An absorbent tampon according to claim 1 wherein the secondaryabsorbent region and the withdrawal mechanism comprises a ribbon ofmaterial.
 4. An absorbent tampon according to claim 1 wherein saidprimary absorbent region is constructed from a same material as saidsecondary absorbent region.
 5. The tampon of claim 1 wherein saidsecondary absorbent region is more hydrophilic than said withdrawalmechanism.
 6. The tampon of claim 1 wherein said of secondary absorbentregion is substantially axially centered about said withdrawalmechanism.
 7. The tampon of claim 1 wherein said primary absorbentregion has a first diameter and said secondary absorbent region has asecond diameter, and wherein said first diameter is larger than saidsecond diameter.
 8. The tampon of claim 1 wherein said secondaryabsorbent region comprises a plurality of discrete pieces of absorbentmaterial separated from each other by portions of said withdrawalmechanism.
 9. The tampon of claim 1 wherein at least a portion of saidsecondary absorbent region is provided with a driving mechanism todivert fluid toward said primary absorbent region of said tampon whereinsaid driving mechanism is selected from the group consisting of ahydrophilicity gradient, a capillarity gradient, and an osmotic drivingforce.
 10. An absorbent tampon having an insertion end and a withdrawalend said tampon comprising: a primary absorbent region, disposed towardsaid insertion end; a secondary absorbent region; a withdrawalmechanism; wherein said primary absorbent region has a first absorbencyand a first density, said secondary absorbent region has a secondabsorbency and a second density, and said withdrawal mechanism has athird absorbency, said first absorbency being greater than said secondabsorbency, and said second absorbency being greater than said thirdabsorbency; and said second density being less than said first density;and wherein said primary absorbent region has a first advancing contactangle and said secondary absorbent region has a second advancing contactangle, wherein said second advancing contact angle is greater than saidfirst advancing contact angle.
 11. An absorbent tampon according toclaim 10 wherein said secondary absorbent region comprises an extendedportion of an overwrap.
 12. An absorbent tampon according to claim 11wherein the secondary absorbent region and said withdrawal mechanismcomprises a ribbon of material.
 13. The tampon of claim 10 wherein saidsecondary absorbent region is substantially axially centered about saidwithdrawal mechanism.
 14. The tampon of claim 10 wherein said tamponcomprises a gap between a withdrawal end of said primary absorbentregion and said secondary absorbent region.
 15. The tampon of claim 10wherein at least a portion of said secondary absorbent region isprovided with a driving mechanism to divert fluid toward said primaryabsorbent region of said tampon.